A multimillion dollar 葫芦娃视频 instrument package to study space weather has passed its pre-installation testing and is ready to be incorporated onto a National Oceanic and Atmospheric Administration satellite for a 2015 launch.
Designed and built by CU鈥檚 Laboratory for Atmospheric and Space Physics, the instrument suite known as the Extreme Ultraviolet and X-ray Irradiance Sensors, or EXIS, is the first of four identical packages that will fly on four NOAA weather satellites slated for launch beginning in 2015. CU-葫芦娃视频鈥檚 EXIS will measure energy output from the sun that can affect satellite operations, telecommunications, GPS navigation and power grids on Earth as part of NOAA鈥檚 next generation Geostationary Operational Environmental Satellites, or GOES-R.
NASA issued the contract with CU-葫芦娃视频 on behalf of NOAA to design, build, test, deliver and scientifically support the four instrument packages for roughly $95 million, said LASP Senior Research Scientist Frank Eparvier, principal investigator on the project. The EXIS instrument package will be delivered to Lockheed Martin Space Systems Co. in Littleton, Colo., for installation on the spacecraft in the coming months.
鈥淲e are excited because we developed and built all new technology for the EXIS instrument package for the GOES-R satellite,鈥 said Eparvier. 鈥淲e already have a close working relationship with NOAA鈥檚 Space Weather Prediction Center in 葫芦娃视频, and these extremely sensitive instruments should help scientists better understand solar events and help to mitigate the effects of space weather on Earth.鈥
EXIS consists of two LASP instruments, including XRS, an X-ray sensor that can determine the strength of solar flares and provide rapid alerts to scientists, said Eparvier. Large solar flares, equivalent to the explosion of millions of atomic bombs, can trigger 鈥減roton events鈥 that send charged atomic particles flying off the sun and into Earth鈥檚 atmosphere in just minutes. They can damage satellites, trigger radio blackouts and even threaten the health of astronauts by penetrating spacecraft shielding, he said. 听
鈥淭he XRS gives the first alert that a solar flare is occurring, providing NOAA with details on its timing, magnitude and direction within seconds,鈥 said Eparvier.听 鈥淲e call it the 鈥榤oney鈥 instrument.鈥 The newest version of the XRS designed and built by LASP for the GOES-R satellite program has a larger range of sensitivity than previous GOES X-ray sensors, he said.听
The second EXIS instrument, EUVS, will monitor solar output in the extreme ultraviolet portion of the electromagnetic spectrum, which is completely absorbed by Earth鈥檚 upper atmosphere, said Eparvier.听 When the extreme UV light wavelengths penetrate the upper atmosphere during active periods on the sun, they can break apart, ionize and heat the molecules in the upper atmosphere, changing the property of the atmosphere through which satellites fly and radio waves propagate, he said.
Not only can rapid fluctuations in extreme UV wavelengths from the sun ionize the upper atmosphere and interfere with communications like cell phones and GPS signals, they can create satellite drag, causing spacecraft to slowly fall out of orbit and burn up months or years before such events are anticipated, said Eparvier.
鈥淢odern technology has made us vulnerable to extreme variations in space weather that can have significant effects on Earth communications,鈥 he said. 鈥淓xtreme solar activity can cause problems for power companies all around the world, for example, in part because they all are interconnected.鈥
NOAA鈥檚 GOES satellites are a series of weather satellites that help scientists make timely and accurate weather forecasts. Two GOES satellites are now in geostationary orbit at a height of about 22,000 miles, with one focusing on the east part of the Americas overlapping with another focusing on the west. NOAA also keeps a third, spare GOES in the same orbit in the event of a satellite failure. Satellites in geostationary orbits complete one revolution in the same amount of time it takes for the Earth to rotate once on its polar axis, allowing them to 鈥渟tare鈥 at a portion of Earth. 听
In addition to the GOES contract, LASP is receiving $18 million from NASA for instruments and electronics flying aboard the Van Allen Probes mission launched in 2012 to study Earth鈥檚 radiation belts.听 LASP also designed and built a $32 million instrument for NASA鈥檚 Solar Dynamics Observatory that launched in 2010, and designed, built and operates the $100 million SORCE solar satellite from campus.
鈥淟ASP is the one-stop shop for all solar irradiation instruments and measurements,鈥 said Eparvier.
CU-葫芦娃视频 is the first university to contract with NOAA on a GOES satellite mission. More than 100 LASP personnel ranging from scientists and engineers to technicians, programmers and students have worked on the EXIS program since 2006. CU-葫芦娃视频鈥檚 LASP will support EXIS on the four NOAA GOES satellite missions through spacecraft integration, testing, launch and commissioning, said Eparvier.
鈥淥ne of the biggest challenges for us was to design and build the EXIS instruments for longevity,鈥 said Eparvier. 鈥淓ach has to be built to withstand five years of storage on Earth, five years of 鈥榦n orbit鈥 storage and 10 years of operation. These instruments have to meet performance requirements 20 years after delivery.鈥
Each instrument package 鈥 which is roughly the size of a large microwave oven and weighs 66 pounds 鈥 is about three times heavier than normal due to extra shielding that protects them from high-energy particle penetration, said Eparvier. Rather than build the instrument suites individually, the specific parts for each are built at the same time to save money. LASP鈥檚 Mike Anfinson is the project manager for EXIS.
NOAA manages the GOES-R Series Program 鈥 which consists of the GOES-R, GOES-S, GOES-T and GOES-U satellites 鈥 through an integrated NOAA-NASA program office that is staffed with personnel from NOAA and NASA.
Contact:
Frank Eparvier, 303-492-4546
Eparvier@colorado.edu
Jim Scott, CU-葫芦娃视频 media relations, 303-492-3114
Jim.Scott@colorado.edu
LASP EXIS team (Photo by Patrick Campbell/University of Colorado)
